WO2008110707A2 - Ventilation duct including noise reduction means - Google Patents

Abstract

The invention relates to a ventilation duct (10) for the air conditioning system of the passenger compartment of a vehicle, that comprises noise reduction means, characterised in that the duct includes an upstream section (12) with an inlet mouth (14) and a turning section (20), and in that the noise reduction means include a reflection area (30) provided in the turning section (20) opposite the upstream section (12) and capable of reflecting at least a portion of the incident waves (11) towards the inlet mouth (14).

Description

 VENTILATION CONDUCT HAVING MEANS FOR NOISE ATTENUATION

The present invention relates to a ventilation duct for a vehicle cabin air-conditioning system comprising noise attenuation means.

The air conditioning system for a passenger compartment of a motor vehicle generally comprises a heat treatment unit for the air which is circulated to the passenger compartment by a fan motor. Various ventilation ducts allow the circulation of the air driven by the fan of the device to properly located outputs in the passenger compartment, for example windshield, driver, front passenger or rear passenger outputs, at the head level. or feet. With the constant reduction of noise pollution due to the vehicle engine, the air conditioning system has become a more easily perceptible and annoying acoustic source to which the ventilation ducts contribute. These ventilation ducts allow the sound of the fan to propagate in the passenger compartment by simple propagation of sound waves, on the one hand, and on the other hand, are also noise generators due to airflow turbulence generated by their forms and architectures. However, it is now considered that the noise of the fan, perceived by the occupants of the vehicle, is the main source of noise generated by the system. The document FR2871872 describes an acoustic device of a ventilation duct provided with noise attenuation means for a vehicle cabin air-conditioning system. The device described comprises noise attenuation means provided with an acoustic cavity placed in the air flow in the conduit. The cavity, placed on a portion of the straight or slightly curved conduit, consists of a localized expansion of the conduit with abrupt upstream and downstream transitions.

Although giving perfectly satisfactory in certain cases of implantation in a vehicle, such a device, relatively bulky, may not be suitable for other cases, especially when the available space for the implementation of noise attenuation means on the conduit is very limited.

It is an object of the present invention to provide a conduit of the aforementioned type in which the conduit comprises an upstream section provided with an inlet mouth and a turning section, and wherein the noise attenuation means comprise a reflection zone located in the turn section, facing the upstream section, and adapted to reflect at least part of the incident waves to the inlet mouth. According to other advantageous features of the invention which can be taken separately or in combination: the reflection zone is flat; the reflection zone is oriented so that it forms an angle of at least 90 degrees with respect to a longitudinal axis of the upstream section taken in the vicinity of the corner section;

- The surface of the reflection zone is greater than the surface of a projection of a section of the upstream section on the corner section, along a longitudinal axis of the upstream section near the corner section; a projection of a section of a downstream section of the conduit on the turning section, along a longitudinal axis of the downstream section taken near the turning section on this corner section, is outside the zone of the zone of reflection ; the section of the duct situated between the upstream section and the reflection zone in the turning section and / or the section of the duct situated between the reflection zone in the turning section and a downstream section varies in a continuous manner; the reflective zone is connected to the portions of the conduit which are adjacent thereto by means of leaves; an external clearance is provided between the upstream section and the reflection zone; an internal boss is provided at the connection of the upstream section and the corner section, upstream of the reflection zone; the ratio of the section corresponding to the maximum height h of the boss with the section of the upstream section is substantially 0.2; the turning section takes the form of a bent portion whose angle between the two arms of the bend is between 30 and 150 °; Another object of the invention is directed towards a motor vehicle comprising an air conditioning system provided with a motorcycle fan and an air outlet in a passenger compartment of the vehicle, connected by a conduit according to the invention, the upstream section. being connected to the fan motor so that air flows from upstream to downstream of the fan motor to the upstream section and then to the downstream section via the corner section.

Advantageously from the acoustic point of view, the reflection zone has the effect of reducing the amplitude of the sound waves circulating thereon at the exit of the duct and over many frequency bands.

Other advantages derive from the location of the reflection zone on a small section of the duct requiring only a small increase in the volume of the duct to be effective. The reflection zone is shifted on the small section, which allows to provide an empty expansion zone. Since this zone does not cause turbulence or other undesirable degradations of the flow, the zones of reflection and expansion are in fact transparent for the flow of air.

It follows that the invention can be implemented without difficulty by modifying the shape of the wall of the duct itself and therefore be made at low cost during the manufacture of the duct.

Other characteristics and advantages of the invention will become clear from reading the following description of the nonlimiting embodiment thereof, in conjunction with the appended drawings in which:

FIG. 1 is a schematic section of a first embodiment of a duct comprising a corner section according to the state of the technical, without acoustic device, leads in which the flow of air is represented by arrows,

FIG. 2 is a section of the duct of FIG. 1, in which acoustic waves are shown; FIG. 3 is a diagrammatic section of a duct comprising a curve section with an acoustic device according to the invention; in which the flow of air is represented by arrows,

FIG. 4 is a section of the duct of FIG. 3, in which acoustic waves are shown; FIG. 5 is a perspective view of a duct according to the invention, a section of which is shown in section in FIGS. and 7,

FIGS. 6, 8, 10 and 12 are views corresponding to FIG. 3 for embodiments,

FIGS. 7, 9, 11 and 13 are views corresponding to FIG. 4 for the embodiments of FIGS. 6, 8, 10 and FIG.

1 2,

FIGS. 14 and 16 are sections corresponding to FIG. 6 or 7 to highlight the dimensions,

FIG. 15 is a section corresponding to FIGS. 8 or 9 for highlighting the dimensions,

FIG. 17 is a section corresponding to an arrangement of the embodiment of FIGS. 6 and 7,

- Figure 18 is a section corresponding to Figures 12 or 13 to highlight the dimensions. Traditionally, a motor vehicle is equipped with a ventilation system for the passenger compartment. The ventilation system generally comprises an air heat treatment unit, between an outside air inlet supplemented, where appropriate, by a recirculated air intake and air outlets in the passenger compartment. The air is circulated from the air inlet (s) to the passenger compartment by a motorcycle fan.

Various ventilation ducts allow the transport of the air driven by the fan of the device to properly located outputs in the passenger compartment, for example the windshield outlets, driver, front passenger or rear passenger, at the head or feet.

The noise emitted, in particular by the fan motor, because of the mixing of the air for example, is transmitted to the passenger compartment by the ducts.

In the embodiment of a pipe 100 bent according to the state of the art shown in FIGS. 1 and 2, in the direction of air flow in the pipe, that is to say from upstream to downstream, a Incident acoustic wave 10A incident is integrally transmitted between an upstream section 120 of the duct connected to an inlet mouth 140 of the duct and a downstream section 160 connected to an outlet mouth 180 of the duct, despite the presence of a corner in turn 200 As schematized in FIG. 2, the transmitted wave 1 10B is of the same amplitude as the incident wave 1 10A.

The noise emitted for example by the fan motor side inlet mouth 140 is not damped in the duct 100.

According to the invention, an acoustic device is placed in a bent duct 10, the acoustic device comprising noise attenuation means. The bent ventilation duct 10 according to the invention comprises an upstream section 12 connected to a turn section 20. The air is intended to flow from upstream to downstream, from the apparatus to the upstream section 12 and then to the section of Turn 20. In Figures 4, 7, 9, 1 1 and

13, the incident wave 11 of the noise in the duct 10 is shown in thick solid lines, the transmitted wave 11 T to the outlet mouth of the duct 18 in solid single lines, and the reflected wave 1 1 R in dotted lines.

The notion of turning section 20 must be understood in the sense of a bent portion whose angle formed by the two arms of the bend is between 30 and 150 degrees.

The noise attenuation means comprise, in the turning section 20 which forms a bend of the duct 10, a reflection zone 30, drawn in bold lines in the figures. The frequency response of the characteristic in reflection of this zone 30 is a function of the material used and its thickness. It is thus possible to favor the attenuation of a particular frequency or frequency band. The reflection zone 30 is located in the duct 10, outside of the turning section 20, facing the upstream section 12, at a distance from a portion of the bent wall of the corner section 20 which includes the corner point of the bend. . The reflection zone 30 is preferably flat but may also present bumps and more generally deformations of various shapes so as to match the internal shape of the duct 10.

The orientation of the reflection zone 30 is such that the incident waves 11 1 are reflected substantially in the direction of the inlet mouth 14, that is to say in a direction other than those leading to the point of contact. turn of the turning portion 20 or leading towards the outlet mouth 18. This prevents the reflected waves 1 1 R from propagating towards the outlet mouth 18.

The dimensions of the reflection zone 30 and its positioning are defined as a function of the section of the upstream section 12. According to the invention, the projection of the section of the upstream section 12, along its longitudinal axis around the elbow, on the turn section 20 must, for optimum efficiency, be entirely on the reflection zone 30. In other words, the surface of the reflection zone 30 is greater than or equal to the surface of this projection of the section of the upstream section 12 on an average plane of the reflection zone 30.

Similarly, for optimum efficiency, the projection of the section of the downstream section 16, along its longitudinal axis taken around the elbow, on the turn section 20 is outside the reflection zone 30. In the illustrated examples in FIGS. 14 and 18, the width D of the duct 10, in the upstream section 12 near the cornering section 20, determines the length L of the reflection zone 30.

As shown in FIGS. 3, 6, 8 and 10, the duct 10 may have an empty expansion zone 32 disposed near the reflection zone 30. This zone 32 is a dead zone for the flow, it is that is, an area in which it can be considered that there is no flow or flow so small that it is considered insignificant. In this way, the empty zone 32 can be considered as not producing a pressure drop. To limit the losses, the section of the duct 10 is arranged. Between the upstream section 12 and the reflection zone 30 in the turn section 20 and between the reflection zone 30 in the turn section 20 and the downstream section 16, the section of the conduit 10 varies continuously. In doing so, the pressure losses are reduced, without prejudice to the reflection of the sound waves on the reflection zone 30.

According to a first embodiment of the invention, shown in Figures 3 and 4, the reflection zone 30 is oriented such that it is at an angle equal to 90 degrees with respect to the longitudinal axis of the upstream section 12 near the turning section. This angle is calculated in the anti-trigonometric direction from the longitudinal axis of the upstream section 12. In other words, the orientation of the reflection zone 30 is such that it is substantially parallel to the axis of the downstream section. 16 located near the turn section 20. According to a second embodiment of the invention, shown in Figures 6, 7, and 16, the reflection zone 30 is oriented such that it makes an angle greater than 90 degrees relative to the longitudinal axis of the upstream section 12 near the turn section 20. As in the first embodiment, this angle is calculated in the anti-trigonometric direction from the longitudinal axis of the upstream section 12. More precisely, in the figures, the value of this angle is 1 10 degrees. In the exemplary embodiment shown in FIG. 16, to describe the orientation of the reflection zone, an angle is defined with respect to the longitudinal axis of the downstream section 16 of the duct 10. This angle denoted a in FIG. a value of about 10 degrees in this example. This angle is calculated in the anti-trigonometric direction from the longitudinal axis of the downstream section 16 of the duct 10. This embodiment makes it possible to increase the reflection of the incident waves 11 towards the upstream section 12 with respect to the first mode. of realization. As a variant, for an optimal continuity of the variation of the section of the conduit 10, in the embodiment of FIG. 17, the reflection zone 30 is connected to the portions of the conduit 10 which are adjacent to it via fillet , indicated by arrows. According to a third embodiment of the invention, represented in FIGS. 8 and 9, an internal boss 36 is made at the connection of the upstream section 12 and the corner section 20 just upstream of the reflection zone 30. By reproducing the beginning of a conventional turn, this boss 36 allows a better flow of air in the turn section 20, giving a turning pulse. Advantageously, the ratio of the section corresponding to the maximum height of the boss 36 with the section of the upstream section is substantially 0.2. In FIG. 15, the height of this boss 36 is denoted h. A fourth embodiment shown in Figures 10 and 11, presents both the features of the second and third embodiments. The geometry of the duct is borrowed from the second embodiment and in particular the orientation of the reflection zone 30, and a boss 36 of the type of that made in the third embodiment is added. This fourth embodiment then advantageously combines the advantages of these embodiments from which it is derived.

According to a fifth embodiment shown in FIGS. 12, 13 and 18, an external clearance 34 is formed between the upstream section 12 and the reflection zone 30. This embodiment has the advantage of avoiding the formation of vortices in the flow of air at the empty expansion zone 32 to facilitate the flow of air in the conduit 10. This external clearance 34 then allows to expand the empty expansion zone 32 upstream of the zone of Reflection 30. The conduit 10, object of the invention can be obtained by injection or blowing.

The duct 10 according to the invention is intended to be connected to an air conditioning apparatus comprising a fan motor, for example in the manner illustrated in FIG. 5. The upstream section 12 is then connected to a straight section of a line 40 of which the upstream free end 42 is provided to be connected to an air conditioning unit.

Claims

1) Ventilation duct (10) for a vehicle cabin air-conditioning system comprising an upstream section (12) provided with an inlet mouth (14) and a turning section (20), and means for noise attenuation comprising a reflection zone (30) located in the turn section (20), facing the upstream section (12), and able to reflect at least part of the incident waves (1 11) towards the mouth of the input (14) characterized in that a projection of a section of a downstream section (16) of the duct (10) on the turning section (20), along a longitudinal axis of the downstream section (16) taken around of the turning section on this turn section (20) is outside the zone of the reflection zone.

2) Ventilation duct (10) according to claim 1, characterized in that the reflection zone (30) is flat.

3) ventilation duct (10) according to any one of the preceding claims, characterized in that the reflection zone (30) is oriented such that it forms an angle, calculated in the anti-trigonometric direction from the longitudinal axis of the upstream section 12, at least 90 degrees with respect to a longitudinal axis of the upstream section (12) taken in the vicinity of the turning section (20).

4) ventilation duct (10) according to any one of the preceding claims, characterized in that the surface of the reflection zone is greater than the surface of a projection of a section of the upstream section on the corner section, along a longitudinal axis of the upstream section around the corner section.

5) Ventilation duct (10) according to any one of the preceding claims, characterized in that the section of the duct

(10) lying between the upstream section (12) and the reflection zone (30) in the turning section (20) and / or the section of the channel (10) lying between the reflection zone (30) in the turn section (20) and a downstream section (16) varies continuously. 6) ventilation duct (10) according to any one of the preceding claims, characterized in that the reflection zone (30) is connected to the portions of the duct (10) adjacent thereto by means of holidays. 7) ventilation duct (10) according to any one of the preceding claims, characterized in that an external clearance (34) is provided between the upstream section (12) and the reflection zone (30).

8) ventilation duct (10) according to any one of the preceding claims, characterized in that an inner boss (36) is provided at the connection of the upstream section (12) and the turn section (20), upstream of the reflection zone (30).

9) ventilation duct (10) according to the preceding claim, characterized in that the ratio of the section corresponding to the maximum height (h) of the boss (36) with the section of the upstream section (12) is substantially 0.2 .

10) ventilation duct (10) according to any one of the preceding claims, characterized in that the turning section (20) takes the form of a bent portion whose angle between the two arms of the elbow is between 30 and 150 °. 1 1) A motor vehicle comprising an air conditioning system provided with a motorcycle fan and an air outlet in a passenger compartment of the vehicle, connected by a duct (10) according to any one of the preceding claims, the upstream section ( 12) being connected to the fan motor so that air flows from upstream to downstream of the fan motor to the upstream section (12) and then to the downstream section (16) via the turning section (20).